X-GM-THRID: 1208160154551123032 X-Gmail-Labels: rsgb lf X-Gmail-Received: 3fb29cc188d6125630f2e8585e0de7212ac08a1d Delivered-To: daveyxm@gmail.com Received: by 10.64.249.17 with SMTP id w17cs159730qbh; Thu, 6 Jul 2006 06:08:30 -0700 (PDT) Received: by 10.48.80.3 with SMTP id d3mr449961nfb; Thu, 06 Jul 2006 06:08:29 -0700 (PDT) Return-Path: Received: from post.thorcom.com (post.thorcom.com [193.82.116.20]) by mx.gmail.com with ESMTP id k9si8186209nfc.2006.07.06.06.08.29; Thu, 06 Jul 2006 06:08:29 -0700 (PDT) Received-SPF: neutral (gmail.com: 193.82.116.20 is neither permitted nor denied by best guess record for domain of owner-rsgb_lf_group@blacksheep.org) Received: from majordom by post.thorcom.com with local (Exim 4.14) id 1FyTXp-00066F-Dn for rs_out_1@blacksheep.org; Thu, 06 Jul 2006 14:05:25 +0100 Received: from [193.82.116.32] (helo=relay1.thorcom.net) by post.thorcom.com with esmtp (Exim 4.14) id 1FyTXo-000666-VF for rsgb_lf_group@blacksheep.org; Thu, 06 Jul 2006 14:05:24 +0100 Received: from hestia.herts.ac.uk ([147.197.200.9]) by relay1.thorcom.net with esmtp (Exim 4.62) (envelope-from ) id 1FyTXj-0003iR-Uo for rsgb_lf_group@blacksheep.org; Thu, 06 Jul 2006 14:05:24 +0100 Received: from [147.197.215.113] (helo=tucana.herts.ac.uk) by hestia.herts.ac.uk with esmtp (Exim 3.22 #1) id 1FyTXc-0000GA-00 for rsgb_lf_group@blacksheep.org; Thu, 06 Jul 2006 14:05:12 +0100 Received: from [147.197.164.230] (helo=RD40002) by tucana.herts.ac.uk with esmtp (Exim 4.44) id 1FyTXb-0007Si-3O for rsgb_lf_group@blacksheep.org; Thu, 06 Jul 2006 14:05:11 +0100 From: "james moritz" To: Date: Thu, 6 Jul 2006 14:05:10 +0100 Message-ID: <000001c6a0fc$cfc5b040$e6a4c593@RD40002> MIME-Version: 1.0 X-Priority: 3 (Normal) X-MSMail-Priority: Normal X-Mailer: Microsoft Outlook, Build 10.0.4510 Importance: Normal In-Reply-To: X-MimeOLE: Produced By Microsoft MimeOLE V6.00.2900.2869 X-UH-MailScanner: No Virus detected X-UH-MailScanner-Information: X-H-UH-MailScanner: No Virus detected X-UH-MailScanner-From: j.r.moritz@herts.ac.uk X-Spam-Score: -0.7 (/) X-Spam-Report: autolearn=disabled,AWL=-0.745 Subject: LF: RE: Loading Coil Q Content-Type: text/plain; charset="us-ascii" Content-Transfer-Encoding: quoted-printable X-Spam-Checker-Version: SpamAssassin 2.63 (2004-01-11) on post.thorcom.com X-Spam-Level: X-Spam-Status: No, hits=0.0 required=5.0 tests=none autolearn=no version=2.63 X-SA-Exim-Scanned: Yes Sender: owner-rsgb_lf_group@blacksheep.org Precedence: bulk Reply-To: rsgb_lf_group@blacksheep.org X-Listname: rsgb_lf_group X-SA-Exim-Rcpt-To: rs_out_1@blacksheep.org X-SA-Exim-Scanned: No; SAEximRunCond expanded to false Status: O X-Status: X-Keywords: X-UID: 5250 Dear Gary, LF Group, The technique I use is like this -=20 Select a low-loss capacitor (polystyrene, silver-mica, polypropylene, = air variable, etc) that will resonate the coil near the frequency of = interest and connect in series with the coil. Connect this series L/C across the output of a sine-wave source with a = known output impedance (sig gen, function generator), Rs, usually 50R. Monitor = the output voltage (using scope, RX + millivoltmeter, SLM, etc.) and adjust = the frequency (or capacitance) for minimum output voltage (i.e. series resonance) Measure the output voltage at the minimum (Vmin), then disconnect L/C = and measure the open-circuit voltage at the generator output (Voc). The equivalent series resistance of the inductor (RL) is then: RL =3D Rs.Vmin/(Voc-Vmin) RL is usually what you want to know, but you can find Q =3D = (2.pi.f.L)/RL where f is the frequency.=20 You can also calculate L if you know what C and f is: L =3D (1/(2.pi.f.sqrt(C)))^2 If your voltage measurement capability is not very accurate, or you are = not sure exactly what the sig gen output impedance is, you can use a substitution method - note Vmin voltage L/C series resonant as before, = then replace L/C with different resistors until you find the value that gives = the same Vmin - RL is then the same as this resistor. If you use a scope or wide-band voltmeter to measure Vmin, errors can be caused for high values of Q (100 or more) due to harmonics in the output = of the signal source. This is fairly obvious on the scope screen. Using a selective level meter, or the more cumbersome Rx + audio voltmeter, eliminates this problem. The ideal tool for the job is a selective level meter with tracking generator - I usually use a W&G SPM6/PS6. I have = used this technique successfully from audio to HF, with a wide range of inductors. If testing a large loading coil, be careful to arrange things = to keep the coil well separated from the test gear, large metal objects, = the ground, yourself etc., otherwise Q can be substantially reduced by the losses induced by the coil's field. Cheers, Jim Moritz 73 de M0BMU